from functools import reduce
import itertools
from operator import add

from sympy import (
    Add, Mul, Pow, Symbol, exp, sqrt, symbols, sympify, cse,
    Matrix, S, cos, sin, Eq, Function, Tuple, CRootOf,
    IndexedBase, Idx, Piecewise, O, signsimp
)
from sympy.core.function import count_ops
from sympy.simplify.cse_opts import sub_pre, sub_post
from sympy.functions.special.hyper import meijerg
from sympy.simplify import cse_main, cse_opts
from sympy.utilities.iterables import subsets
from sympy.testing.pytest import XFAIL, raises
from sympy.matrices import (MutableDenseMatrix, MutableSparseMatrix,
        ImmutableDenseMatrix, ImmutableSparseMatrix)
from sympy.matrices.expressions import MatrixSymbol


w, x, y, z = symbols('w,x,y,z')
x0, x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12 = symbols('x:13')


def test_numbered_symbols():
    ns = cse_main.numbered_symbols(prefix='y')
    assert list(itertools.islice(
        ns, 0, 10)) == [Symbol('y%s' % i) for i in range(0, 10)]
    ns = cse_main.numbered_symbols(prefix='y')
    assert list(itertools.islice(
        ns, 10, 20)) == [Symbol('y%s' % i) for i in range(10, 20)]
    ns = cse_main.numbered_symbols()
    assert list(itertools.islice(
        ns, 0, 10)) == [Symbol('x%s' % i) for i in range(0, 10)]

# Dummy "optimization" functions for testing.


def opt1(expr):
    return expr + y


def opt2(expr):
    return expr*z


def test_preprocess_for_cse():
    assert cse_main.preprocess_for_cse(x, [(opt1, None)]) == x + y
    assert cse_main.preprocess_for_cse(x, [(None, opt1)]) == x
    assert cse_main.preprocess_for_cse(x, [(None, None)]) == x
    assert cse_main.preprocess_for_cse(x, [(opt1, opt2)]) == x + y
    assert cse_main.preprocess_for_cse(
        x, [(opt1, None), (opt2, None)]) == (x + y)*z


def test_postprocess_for_cse():
    assert cse_main.postprocess_for_cse(x, [(opt1, None)]) == x
    assert cse_main.postprocess_for_cse(x, [(None, opt1)]) == x + y
    assert cse_main.postprocess_for_cse(x, [(None, None)]) == x
    assert cse_main.postprocess_for_cse(x, [(opt1, opt2)]) == x*z
    # Note the reverse order of application.
    assert cse_main.postprocess_for_cse(
        x, [(None, opt1), (None, opt2)]) == x*z + y


def test_cse_single():
    # Simple substitution.
    e = Add(Pow(x + y, 2), sqrt(x + y))
    substs, reduced = cse([e])
    assert substs == [(x0, x + y)]
    assert reduced == [sqrt(x0) + x0**2]

    subst42, (red42,) = cse([42])  # issue_15082
    assert len(subst42) == 0 and red42 == 42
    subst_half, (red_half,) = cse([0.5])
    assert len(subst_half) == 0 and red_half == 0.5


def test_cse_single2():
    # Simple substitution, test for being able to pass the expression directly
    e = Add(Pow(x + y, 2), sqrt(x + y))
    substs, reduced = cse(e)
    assert substs == [(x0, x + y)]
    assert reduced == [sqrt(x0) + x0**2]
    substs, reduced = cse(Matrix([[1]]))
    assert isinstance(reduced[0], Matrix)

    subst42, (red42,) = cse(42)  # issue 15082
    assert len(subst42) == 0 and red42 == 42
    subst_half, (red_half,) = cse(0.5)  # issue 15082
    assert len(subst_half) == 0 and red_half == 0.5

def test_cse_not_possible():
    # No substitution possible.
    e = Add(x, y)
    substs, reduced = cse([e])
    assert substs == []
    assert reduced == [x + y]
    # issue 6329
    eq = (meijerg((1, 2), (y, 4), (5,), [], x) +
          meijerg((1, 3), (y, 4), (5,), [], x))
    assert cse(eq) == ([], [eq])


def test_nested_substitution():
    # Substitution within a substitution.
    e = Add(Pow(w*x + y, 2), sqrt(w*x + y))
    substs, reduced = cse([e])
    assert substs == [(x0, w*x + y)]
    assert reduced == [sqrt(x0) + x0**2]


def test_subtraction_opt():
    # Make sure subtraction is optimized.
    e = (x - y)*(z - y) + exp((x - y)*(z - y))
    substs, reduced = cse(
        [e], optimizations=[(cse_opts.sub_pre, cse_opts.sub_post)])
    assert substs == [(x0, (x - y)*(y - z))]
    assert reduced == [-x0 + exp(-x0)]
    e = -(x - y)*(z - y) + exp(-(x - y)*(z - y))
    substs, reduced = cse(
        [e], optimizations=[(cse_opts.sub_pre, cse_opts.sub_post)])
    assert substs == [(x0, (x - y)*(y - z))]
    assert reduced == [x0 + exp(x0)]
    # issue 4077
    n = -1 + 1/x
    e = n/x/(-n)**2 - 1/n/x
    assert cse(e, optimizations=[(cse_opts.sub_pre, cse_opts.sub_post)]) == \
        ([], [0])


def test_multiple_expressions():
    e1 = (x + y)*z
    e2 = (x + y)*w
    substs, reduced = cse([e1, e2])
    assert substs == [(x0, x + y)]
    assert reduced == [x0*z, x0*w]
    l = [w*x*y + z, w*y]
    substs, reduced = cse(l)
    rsubsts, _ = cse(reversed(l))
    assert substs == rsubsts
    assert reduced == [z + x*x0, x0]
    l = [w*x*y, w*x*y + z, w*y]
    substs, reduced = cse(l)
    rsubsts, _ = cse(reversed(l))
    assert substs == rsubsts
    assert reduced == [x1, x1 + z, x0]
    l = [(x - z)*(y - z), x - z, y - z]
    substs, reduced = cse(l)
    rsubsts, _ = cse(reversed(l))
    assert substs == [(x0, -z), (x1, x + x0), (x2, x0 + y)]
    assert rsubsts == [(x0, -z), (x1, x0 + y), (x2, x + x0)]
    assert reduced == [x1*x2, x1, x2]
    l = [w*y + w + x + y + z, w*x*y]
    assert cse(l) == ([(x0, w*y)], [w + x + x0 + y + z, x*x0])
    assert cse([x + y, x + y + z]) == ([(x0, x + y)], [x0, z + x0])
    assert cse([x + y, x + z]) == ([], [x + y, x + z])
    assert cse([x*y, z + x*y, x*y*z + 3]) == \
        ([(x0, x*y)], [x0, z + x0, 3 + x0*z])


@XFAIL # CSE of non-commutative Mul terms is disabled
def test_non_commutative_cse():
    A, B, C = symbols('A B C', commutative=False)
    l = [A*B*C, A*C]
    assert cse(l) == ([], l)
    l = [A*B*C, A*B]
    assert cse(l) == ([(x0, A*B)], [x0*C, x0])


# Test if CSE of non-commutative Mul terms is disabled
def test_bypass_non_commutatives():
    A, B, C = symbols('A B C', commutative=False)
    l = [A*B*C, A*C]
    assert cse(l) == ([], l)
    l = [A*B*C, A*B]
    assert cse(l) == ([], l)
    l = [B*C, A*B*C]
    assert cse(l) == ([], l)


@XFAIL # CSE fails when replacing non-commutative sub-expressions
def test_non_commutative_order():
    A, B, C = symbols('A B C', commutative=False)
    x0 = symbols('x0', commutative=False)
    l = [B+C, A*(B+C)]
    assert cse(l) == ([(x0, B+C)], [x0, A*x0])


@XFAIL # Worked in gh-11232, but was reverted due to performance considerations
def test_issue_10228():
    assert cse([x*y**2 + x*y]) == ([(x0, x*y)], [x0*y + x0])
    assert cse([x + y, 2*x + y]) == ([(x0, x + y)], [x0, x + x0])
    assert cse((w + 2*x + y + z, w + x + 1)) == (
        [(x0, w + x)], [x0 + x + y + z, x0 + 1])
    assert cse(((w + x + y + z)*(w - x))/(w + x)) == (
        [(x0, w + x)], [(x0 + y + z)*(w - x)/x0])
    a, b, c, d, f, g, j, m = symbols('a, b, c, d, f, g, j, m')
    exprs = (d*g**2*j*m, 4*a*f*g*m, a*b*c*f**2)
    assert cse(exprs) == (
        [(x0, g*m), (x1, a*f)], [d*g*j*x0, 4*x0*x1, b*c*f*x1]
)

@XFAIL
def test_powers():
    assert cse(x*y**2 + x*y) == ([(x0, x*y)], [x0*y + x0])


def test_issue_4498():
    assert cse(w/(x - y) + z/(y - x), optimizations='basic') == \
        ([], [(w - z)/(x - y)])


def test_issue_4020():
    assert cse(x**5 + x**4 + x**3 + x**2, optimizations='basic') \
        == ([(x0, x**2)], [x0*(x**3 + x + x0 + 1)])


def test_issue_4203():
    assert cse(sin(x**x)/x**x) == ([(x0, x**x)], [sin(x0)/x0])


def test_issue_6263():
    e = Eq(x*(-x + 1) + x*(x - 1), 0)
    assert cse(e, optimizations='basic') == ([], [True])


def test_dont_cse_tuples():
    from sympy import Subs
    f = Function("f")
    g = Function("g")

    name_val, (expr,) = cse(
        Subs(f(x, y), (x, y), (0, 1))
        + Subs(g(x, y), (x, y), (0, 1)))

    assert name_val == []
    assert expr == (Subs(f(x, y), (x, y), (0, 1))
            + Subs(g(x, y), (x, y), (0, 1)))

    name_val, (expr,) = cse(
        Subs(f(x, y), (x, y), (0, x + y))
        + Subs(g(x, y), (x, y), (0, x + y)))

    assert name_val == [(x0, x + y)]
    assert expr == Subs(f(x, y), (x, y), (0, x0)) + \
        Subs(g(x, y), (x, y), (0, x0))


def test_pow_invpow():
    assert cse(1/x**2 + x**2) == \
        ([(x0, x**2)], [x0 + 1/x0])
    assert cse(x**2 + (1 + 1/x**2)/x**2) == \
        ([(x0, x**2), (x1, 1/x0)], [x0 + x1*(x1 + 1)])
    assert cse(1/x**2 + (1 + 1/x**2)*x**2) == \
        ([(x0, x**2), (x1, 1/x0)], [x0*(x1 + 1) + x1])
    assert cse(cos(1/x**2) + sin(1/x**2)) == \
        ([(x0, x**(-2))], [sin(x0) + cos(x0)])
    assert cse(cos(x**2) + sin(x**2)) == \
        ([(x0, x**2)], [sin(x0) + cos(x0)])
    assert cse(y/(2 + x**2) + z/x**2/y) == \
        ([(x0, x**2)], [y/(x0 + 2) + z/(x0*y)])
    assert cse(exp(x**2) + x**2*cos(1/x**2)) == \
        ([(x0, x**2)], [x0*cos(1/x0) + exp(x0)])
    assert cse((1 + 1/x**2)/x**2) == \
        ([(x0, x**(-2))], [x0*(x0 + 1)])
    assert cse(x**(2*y) + x**(-2*y)) == \
        ([(x0, x**(2*y))], [x0 + 1/x0])


def test_postprocess():
    eq = (x + 1 + exp((x + 1)/(y + 1)) + cos(y + 1))
    assert cse([eq, Eq(x, z + 1), z - 2, (z + 1)*(x + 1)],
        postprocess=cse_main.cse_separate) == \
        [[(x0, y + 1), (x2, z + 1), (x, x2), (x1, x + 1)],
        [x1 + exp(x1/x0) + cos(x0), z - 2, x1*x2]]


def test_issue_4499():
    # previously, this gave 16 constants
    from sympy.abc import a, b
    B = Function('B')
    G = Function('G')
    t = Tuple(*
        (a, a + S.Half, 2*a, b, 2*a - b + 1, (sqrt(z)/2)**(-2*a + 1)*B(2*a -
        b, sqrt(z))*B(b - 1, sqrt(z))*G(b)*G(2*a - b + 1),
        sqrt(z)*(sqrt(z)/2)**(-2*a + 1)*B(b, sqrt(z))*B(2*a - b,
        sqrt(z))*G(b)*G(2*a - b + 1), sqrt(z)*(sqrt(z)/2)**(-2*a + 1)*B(b - 1,
        sqrt(z))*B(2*a - b + 1, sqrt(z))*G(b)*G(2*a - b + 1),
        (sqrt(z)/2)**(-2*a + 1)*B(b, sqrt(z))*B(2*a - b + 1,
        sqrt(z))*G(b)*G(2*a - b + 1), 1, 0, S.Half, z/2, -b + 1, -2*a + b,
        -2*a))
    c = cse(t)
    ans = (
        [(x0, 2*a), (x1, -b), (x2, x0 + x1), (x3, x2 + 1), (x4, sqrt(z)), (x5,
        B(b - 1, x4)), (x6, -x0), (x7, (x4/2)**(x6 + 1)*G(b)*G(x3)), (x8,
        x7*B(x2, x4)), (x9, B(b, x4)), (x10, x7*B(x3, x4))],
        [(a, a + S.Half, x0, b, x3, x5*x8, x4*x8*x9, x10*x4*x5, x10*x9,
        1, 0, S.Half, z/2, x1 + 1, b + x6, x6)])
    assert ans == c


def test_issue_6169():
    r = CRootOf(x**6 - 4*x**5 - 2, 1)
    assert cse(r) == ([], [r])
    # and a check that the right thing is done with the new
    # mechanism
    assert sub_post(sub_pre((-x - y)*z - x - y)) == -z*(x + y) - x - y


def test_cse_Indexed():
    len_y = 5
    y = IndexedBase('y', shape=(len_y,))
    x = IndexedBase('x', shape=(len_y,))
    i = Idx('i', len_y-1)

    expr1 = (y[i+1]-y[i])/(x[i+1]-x[i])
    expr2 = 1/(x[i+1]-x[i])
    replacements, reduced_exprs = cse([expr1, expr2])
    assert len(replacements) > 0


def test_cse_MatrixSymbol():
    # MatrixSymbols have non-Basic args, so make sure that works
    A = MatrixSymbol("A", 3, 3)
    assert cse(A) == ([], [A])

    n = symbols('n', integer=True)
    B = MatrixSymbol("B", n, n)
    assert cse(B) == ([], [B])

def test_cse_MatrixExpr():
    from sympy import MatrixSymbol
    A = MatrixSymbol('A', 3, 3)
    y = MatrixSymbol('y', 3, 1)

    expr1 = (A.T*A).I * A * y
    expr2 = (A.T*A) * A * y
    replacements, reduced_exprs = cse([expr1, expr2])
    assert len(replacements) > 0

    replacements, reduced_exprs = cse([expr1 + expr2, expr1])
    assert replacements

    replacements, reduced_exprs = cse([A**2, A + A**2])
    assert replacements

def test_Piecewise():
    f = Piecewise((-z + x*y, Eq(y, 0)), (-z - x*y, True))
    ans = cse(f)
    actual_ans = ([(x0, -z), (x1, x*y)],
        [Piecewise((x0 + x1, Eq(y, 0)), (x0 - x1, True))])
    assert ans == actual_ans


def test_ignore_order_terms():
    eq = exp(x).series(x,0,3) + sin(y+x**3) - 1
    assert cse(eq) == ([], [sin(x**3 + y) + x + x**2/2 + O(x**3)])


def test_name_conflict():
    z1 = x0 + y
    z2 = x2 + x3
    l = [cos(z1) + z1, cos(z2) + z2, x0 + x2]
    substs, reduced = cse(l)
    assert [e.subs(reversed(substs)) for e in reduced] == l


def test_name_conflict_cust_symbols():
    z1 = x0 + y
    z2 = x2 + x3
    l = [cos(z1) + z1, cos(z2) + z2, x0 + x2]
    substs, reduced = cse(l, symbols("x:10"))
    assert [e.subs(reversed(substs)) for e in reduced] == l


def test_symbols_exhausted_error():
    l = cos(x+y)+x+y+cos(w+y)+sin(w+y)
    sym = [x, y, z]
    with raises(ValueError):
        cse(l, symbols=sym)


def test_issue_7840():
    # daveknippers' example
    C393 = sympify( \
        'Piecewise((C391 - 1.65, C390 < 0.5), (Piecewise((C391 - 1.65, \
        C391 > 2.35), (C392, True)), True))'
    )
    C391 = sympify( \
        'Piecewise((2.05*C390**(-1.03), C390 < 0.5), (2.5*C390**(-0.625), True))'
    )
    C393 = C393.subs('C391',C391)
    # simple substitution
    sub = {}
    sub['C390'] = 0.703451854
    sub['C392'] = 1.01417794
    ss_answer = C393.subs(sub)
    # cse
    substitutions,new_eqn = cse(C393)
    for pair in substitutions:
        sub[pair[0].name] = pair[1].subs(sub)
    cse_answer = new_eqn[0].subs(sub)
    # both methods should be the same
    assert ss_answer == cse_answer

    # GitRay's example
    expr = sympify(
        "Piecewise((Symbol('ON'), Equality(Symbol('mode'), Symbol('ON'))), \
        (Piecewise((Piecewise((Symbol('OFF'), StrictLessThan(Symbol('x'), \
        Symbol('threshold'))), (Symbol('ON'), true)), Equality(Symbol('mode'), \
        Symbol('AUTO'))), (Symbol('OFF'), true)), true))"
    )
    substitutions, new_eqn = cse(expr)
    # this Piecewise should be exactly the same
    assert new_eqn[0] == expr
    # there should not be any replacements
    assert len(substitutions) < 1


def test_issue_8891():
    for cls in (MutableDenseMatrix, MutableSparseMatrix,
            ImmutableDenseMatrix, ImmutableSparseMatrix):
        m = cls(2, 2, [x + y, 0, 0, 0])
        res = cse([x + y, m])
        ans = ([(x0, x + y)], [x0, cls([[x0, 0], [0, 0]])])
        assert res == ans
        assert isinstance(res[1][-1], cls)


def test_issue_11230():
    # a specific test that always failed
    a, b, f, k, l, i = symbols('a b f k l i')
    p = [a*b*f*k*l, a*i*k**2*l, f*i*k**2*l]
    R, C = cse(p)
    assert not any(i.is_Mul for a in C for i in a.args)

    # random tests for the issue
    from random import choice
    from sympy.core.function import expand_mul
    s = symbols('a:m')
    # 35 Mul tests, none of which should ever fail
    ex = [Mul(*[choice(s) for i in range(5)]) for i in range(7)]
    for p in subsets(ex, 3):
        p = list(p)
        R, C = cse(p)
        assert not any(i.is_Mul for a in C for i in a.args)
        for ri in reversed(R):
            for i in range(len(C)):
                C[i] = C[i].subs(*ri)
        assert p == C
    # 35 Add tests, none of which should ever fail
    ex = [Add(*[choice(s[:7]) for i in range(5)]) for i in range(7)]
    for p in subsets(ex, 3):
        p = list(p)
        R, C = cse(p)
        assert not any(i.is_Add for a in C for i in a.args)
        for ri in reversed(R):
            for i in range(len(C)):
                C[i] = C[i].subs(*ri)
        # use expand_mul to handle cases like this:
        # p = [a + 2*b + 2*e, 2*b + c + 2*e, b + 2*c + 2*g]
        # x0 = 2*(b + e) is identified giving a rebuilt p that
        # is now `[a + 2*(b + e), c + 2*(b + e), b + 2*c + 2*g]`
        assert p == [expand_mul(i) for i in C]


@XFAIL
def test_issue_11577():
    def check(eq):
        r, c = cse(eq)
        assert eq.count_ops() >= \
            len(r) + sum([i[1].count_ops() for i in r]) + \
            count_ops(c)

    eq = x**5*y**2 + x**5*y + x**5
    assert cse(eq) == (
        [(x0, x**4), (x1, x*y)], [x**5 + x0*x1*y + x0*x1])
        # ([(x0, x**5*y)], [x0*y + x0 + x**5]) or
        # ([(x0, x**5)], [x0*y**2 + x0*y + x0])
    check(eq)

    eq = x**2/(y + 1)**2 + x/(y + 1)
    assert cse(eq) == (
        [(x0, y + 1)], [x**2/x0**2 + x/x0])
        # ([(x0, x/(y + 1))], [x0**2 + x0])
    check(eq)


def test_hollow_rejection():
    eq = [x + 3, x + 4]
    assert cse(eq) == ([], eq)


def test_cse_ignore():
    exprs = [exp(y)*(3*y + 3*sqrt(x+1)), exp(y)*(5*y + 5*sqrt(x+1))]
    subst1, red1 = cse(exprs)
    assert any(y in sub.free_symbols for _, sub in subst1), "cse failed to identify any term with y"

    subst2, red2 = cse(exprs, ignore=(y,))  # y is not allowed in substitutions
    assert not any(y in sub.free_symbols for _, sub in subst2), "Sub-expressions containing y must be ignored"
    assert any(sub - sqrt(x + 1) == 0 for _, sub in subst2), "cse failed to identify sqrt(x + 1) as sub-expression"

def test_cse_ignore_issue_15002():
    l = [
        w*exp(x)*exp(-z),
        exp(y)*exp(x)*exp(-z)
    ]
    substs, reduced = cse(l, ignore=(x,))
    rl = [e.subs(reversed(substs)) for e in reduced]
    assert rl == l

def test_cse__performance():
    nexprs, nterms = 3, 20
    x = symbols('x:%d' % nterms)
    exprs = [
        reduce(add, [x[j]*(-1)**(i+j) for j in range(nterms)])
        for i in range(nexprs)
    ]
    assert (exprs[0] + exprs[1]).simplify() == 0
    subst, red = cse(exprs)
    assert len(subst) > 0, "exprs[0] == -exprs[2], i.e. a CSE"
    for i, e in enumerate(red):
        assert (e.subs(reversed(subst)) - exprs[i]).simplify() == 0


def test_issue_12070():
    exprs = [x + y, 2 + x + y, x + y + z, 3 + x + y + z]
    subst, red = cse(exprs)
    assert 6 >= (len(subst) + sum([v.count_ops() for k, v in subst]) +
                 count_ops(red))


def test_issue_13000():
    eq = x/(-4*x**2 + y**2)
    cse_eq = cse(eq)[1][0]
    assert cse_eq == eq


def test_issue_18203():
    eq = CRootOf(x**5 + 11*x - 2, 0) + CRootOf(x**5 + 11*x - 2, 1)
    assert cse(eq) == ([], [eq])


def test_unevaluated_mul():
    eq = Mul(x + y, x + y, evaluate=False)
    assert cse(eq) == ([(x0, x + y)], [x0**2])

def test_issue_18991():
    A = MatrixSymbol('A', 2, 2)
    assert signsimp(-A * A - A) == -A * A - A
